Covering a wide area by a large number of WiFi networks is anticipated to become very popular with Internet-of-things (IoT) and initiatives such as smart cities. Such network configuration is normally realized through deploying a large number of access points (APs) with overlapped coverage. However, the imbalanced traffic load distribution among different APs affects the energy consumption of a WiFi device if it is associated to a loaded AP. This research work aims at predicting the communication-related energy that shall be consumed by a WiFi device if it transferred some amount of data through a certain selected AP. In this paper, a forecast of the energy consumption is proposed to be obtained using an algorithm that is supported by a mathematical model. Consequently, the proposed algorithm can automatically select the best WiFi network (best AP) that the WiFi device can connect to in order to minimize energy consumption. The proposed algorithm is experimentally validated in a realistic lab setting. The observed performance indicates that the algorithm can provide an accurate forecast to the energy that shall be consumed by a WiFi transceiver in sending some amount of data via a specific AP.

M. Ismail, W. Zhuang, Network cooperation for energy saving in green radio communications, IEEE Wireless Communica271

tions 18 (5) (2011) 76–81. doi:10.1109/MWC.2011.6056695.

A. P.Miettinen, J. K. Nurminen, Energy efficiency of mobile clients in cloud computing, in: Proceedings of the 2Nd USENIX

Conference on Hot Topics in Cloud Computing, HotCloud’10, USENIX Association, Berkeley, CA, USA, 2010, pp. 4–4.

URL http://dl.acm.org/citation.cfm?id=1863103.1863107

J. A. Paradiso, T. Starner, Energy scavenging for mobile and wireless electronics, IEEE Pervasive Computing 4 (1) (2005)

–27. doi:10.1109/MPRV.2005.9.

S. Robinson, Cellphone energy gap: Desperately seeking solutions, Tech. rep., Strategy Analytics (2009).

K. Pentikousis, In search of energy-efficient mobile networking, IEEE Communications Magazine 48 (1) (2010) 95–103.

doi:10.1109/MCOM.2010.5394036.

X. Chen, J.Wu, Y. Cai, H. Zhang, T. Chen, Energy-efficiency oriented traffic offloading in wireless networks: A brief survey

and a learning approach for heterogeneous cellular networks, IEEE Journal on Selected Areas in Communications 33 (4)

(2015) 627–640. doi:10.1109/JSAC.2015.2393496.

K. Lee, J. Lee, Y. Yi, I. Rhee, S. Chong, Mobile data offloading: How much can wifi deliver?, IEEE/ACM Transactions on

Networking 21 (2) (2013) 536–550. doi:10.1109/TNET.2012.2218122.

M. Altamimi, A. Abdrabou, K. Naik, A. Nayak, Energy cost models of smartphones for task offloading to the cloud, IEEE

Transactions on Emerging Topics in Computing 3 (3) (2015) 384–398. doi:10.1109/TETC.2014.2387752.

L. Sun, R. K. Sheshadri, W. Zheng, D. Koutsonikolas, Modeling wifi active power/energy consumption in smartphones, in:

IEEE 34th International Conference on Distributed Computing Systems, 2014, pp. 41–51. doi:10.1109/ICDCS.2014.13.

S. Hao, D. Li,W. G. J. Halfond, R. Govindan, Estimating mobile application energy consumption using program analysis, in:

35th International Conference on Software Engineering (ICSE), 2013, pp. 92–101. doi:10.1109/ICSE.2013.6606555.

L. Zhang, B. Tiwana, R. P. Dick, Z. Qian, Z. M. Mao, Z. Wang, L. Yang, Accurate online power estimation and automatic

battery behavior based power model generation for smartphones, in: 2010 IEEE/ACM/IFIP International Conference on

Hardware/Software Codesign and System Synthesis (CODES+ISSS), 2010, pp. 105–114.

M. Dong, L. Zhong, Self-constructive high-rate systemenergymodeling for battery-poweredmobile systems, in: Proceedings

of the 9th international conference on Mobile systems, applications, and services, ACM, 2011, pp. 335–348.

M. M. Carvalho, C. B. Margi, K. Obraczka, J. J. Garcia-Luna-Aceves, Modeling energy consumption in single-hop ieee

11 ad hoc networks, in: Proceedings. 13th International Conference on Computer Communications and Networks (IEEE

Cat. No.04EX969), 2004, pp. 367–372. doi:10.1109/ICCCN.2004.1401671.

X. Wang, J. Yin, D. P. Agrawal, Analysis and optimization of the energy efficiency in the 802.11 dcf, Mobile networks and

applications 11 (2) (2006) 279–286.

A. Garcia-Saavedra, P. Serrano, A. Banchs, G. Bianchi, Energy consumption anatomy of 802.11 devices and its implication

on modeling and design, in: Proceedings of the 8th international conference on Emerging networking experiments and technologies, ACM, 2012, pp. 169–180.

A. Abdrabou, W. Zhuang, Stochastic delay guarantees and statistical call admission control for IEEE 802.11 single-hop ad

hoc networks, IEEE Transactions on Wireless Communications 7 (10) (2008) 3972–3981.

Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) specifications: Further Higher-Speed

Physical Layer Extension in the 2.4 GHz Band, IEEE Std 802.11g/D1.1 (2001).

G. Bianchi, Performance analysis of the ieee 802.11 distributed coordination function, IEEE Journal on Selected Areas in

Communications 18 (3) (2000) 535–547. doi:10.1109/49.840210.

A. Abdrabou, W. Zhuang, Service time approximation in ieee 802.11 single-hop ad hoc networks, IEEE Transactions on

Wireless Communications 7 (1) (2008) 305–313. doi:10.1109/TWC.2008.060530.

M. Xie, M. Haenggi, Towards an end-to-end delay analysis of wireless multihop networks, Ad Hoc Networks 7 (5) (2009)

– 861. doi:http://dx.doi.org/10.1016/j.adhoc.2008.04.010. URL http://www.sciencedirect.com/science/article/pii/S157087050800111X

Microsoft, PsPing v2.1 (2016). URL https://docs.microsoft.com/en-us/sysinternals/downloads/psping

Tamosoft LTD, CommView for WiFi (2018).URL https://www.tamos.com/products/commwifi/